Complexes of silver(II) and silver(III) with ... - ACS Publications

Apr 16, 1973 - Chem., 40, 1174. (1968). ... using 1 mmol of ligand and 2 mmol of silver perchlorate in 30 ml of water except the solution ... An aceto...
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Inorganic Chemistry, Vol. 12, No. 12, I973 2829

Ag Complexes with Tetraaza Ligands

Contribution from W. A. Noyes Laboratory, Department of Chemistry, School of Chemical Sciences, University of Illinois, Urbana, Illinois 61801

Complexes of Silver(I1) and Silver(II1) with Macrocyclic Tetraaza Ligands E. KENT BAREFIELD* and MICHAEL T. MOCELLA Received March 5, 1973 Silver(I1) complexes of four macrocyclic tetraaza ligands have been prepared by disproportionation of Ag(1) in the presence of the ligand. Some of these complexes may be oxidized to silver(II1) species electrochemically or with NO' salts. Spectral and electrochemical properties of the new compounds are reported.

During recent investigations into the coordination chemistry of the ligand in I11 we attempted to remove C1- from

I.

Ia, R, = H; R, =CH,; n = 2 b,n=3 IIa, R, = H; R, = H ; n = 2 b,n=3 111, R, =CH,; R, = H ; n = 2

[NiLCl]C104' using Ag+. When an aqueous solution of the complex was treated with Ag' a rapid color change occurred and a silver mirror formed. This behavior could also be observed when aqueous solutions of Ag(1) and the amine were mixed and a crystalline complex of stoichiometry AgL(ClO& could be isolated from the orange solution after removal of the metallic silver. Further investigation revealed that the general reaction 2Ag'

+ L +. AgL*+ + Ago

occurred when silver(1) salts react with a variety of macrocyclic arnines.'~~Some of these silver(I1) species have been oxidized both chemically and electrochemically to silver(II1) species of substantial stability. Complexes prepared are shown as I-IV. The preparation and properties of these silver(I1) and -(III) complexes are the subject of this report. Experimental Section Preparation of mesod ,5,7,12,12,14-Hexamethyltetraazacyclotetradecanesilver(I1) Perchlorate (la). A solution of 0.83 g of AgC10, (4mmol) in 140 ml of reagent grade CH,CN was treated with 0.77 g of ligand (2 mmol as the dihydrate). This solution became deep yellow orange and a silver mirror formed. Stirring was continued for 20 min. The solution was filtered and reduced to a small volume on a rotary evaporator. The yellow solid was collected and was recrystallized from acetonitrile by addition of ether. The solid was collected and washed with ether and dried in vucuo: yield 0.7 g of deep yellow crystals. Highly purified acetonitrile, did not work ( 1 ) E. KTBarefield and F. Wagner, Inorg. Chem., 12,2435 (1973). (2) A single example of such a disproportionation was recently published: M. 0. Kestner and A. L. Allred, J. Amer. Chem. SOC.,94, 7189 (1972). The complex prepared by these workers is the same as

Ia in this report. (3) A review of the chemistry of these ligands (other than the Nmethylated derivative used in 111) has recently appeared: L. F. Lindoy and D. H. Busch, Prep. Inorg. React., 6, 1 (1971). This reference should be consulted for synthetic details. (4) Acetonitrile was purified by a modification of the precedure given by E. 0. Sherman, Jr., and D. C . Olson, Anal. Chem., 40, 1174 (1 968).

for this reaction. Instead, a white solid results. This was also observed by Kestner and Allred and was characterized as an Ag(1) species.' Preparation of 1,4,8,11 -Tetraazacyclotetradecanesilver(II) Perchlorate (IIa). Ligand (1 g, 5 mmol) was added to a stirred solution of 2.1 g of silver perchlorate (10mmol) in 100 ml of water. A yellow color developed rapidly in the solution and a silver mirror soon formed. After stirring for 1 hr the solution was filtered, acidified to pH 2 with perchloric acid, and concentrated on a rotary evaporator. The orange needles which formed were collected, washed with THF, and dried in vucuo: yield 1.4g. Preparation of 1,4,8,11-Tetramethyl-l,4,8,1 l-tetraazacyclotetradecanesilver(I1)Perchlorate (111). This complex was prepared as above using 1 mmol of ligand and 2 mmol of silver perchlorate in 30 ml of water except the solution was not acidified with perchloric acid before evaporation: yield 0.25 g of dark orange-brown crystals. Preparation of 5,s ,7,12,12,14-Hexamethyl-l,4,8,11 -tetraazacyclotetradeca-1,8-dienesilver(II)Perchlorate (W). A suspension of 1 g of the dihydroperchlorate ligand salt and excess freshly prepared silver(1) oxide was shaken for 4 hr in 200 ml of H,O. The solids were removed by filtration and the pale yellow filtrate was acidified with HClO, and evaporated to a small volume. The yellow crystals were collected, washed with THF, and sucked dry. Conversion to the complex is quite low because of limited solubility of both reagents. Oxidation of Ia to Ib. Under nitrogen a solution of Ia, 0.6 g (1 mmol), in 50 ml of purified CH,CN was treated with 0.15 g (1 mmol) of NOC10,. After stirring for 1 hr ether was added to crystallize a pale yellow solid. This solid was collected and dried in vacuo. It was later found that an identical material could be obtained by the procedure following for oxidation of Ha to IIb. Also, the same complex could be obtained by electrochemical oxidation at a Pt foil electrode. An acetonitrile solution of complex which was 0.1 M in purified (C,H,),NClO, was contained in a three-compartment cell and electrolyzed with a Par Model 173 potentiostat. The new complex reacts instantly with water or other basic solvents to yield violet solutions. At room temperature these solutions exhibit no esr signal upon formation. However, a signal slowly grows with time. At the same time the solution lightens in color and finally becomes yellow. The strong esr signal for this solution is typical of the Ag(I1) complexes in solution. Oxidation of IIa to IIb. Oxidation of this material in acetonitrile proved difficult because of the instability of the product complex. However, the oxidation could be conducted in reagent grade acetonitrile containing concentrated perchloric acid. Ha, 0.2 g, dissolved in ca. 5 ml of CH,CN containing a few drops of concentrated HClO, was treated with NOClO,~H,O until the orange color changed to a very pale yellow. A pale yellow solid commenced to form. This suspension was stirred for ca. 15 min and the solid collected under a blanket of nitrogen, washed with ether, and dried briefly in vacuo. Electrochemical oxidation of this complex could also be performed but conversion to Ag(II1) was low because of the competing decomposition to Ag(I1). The diamagnetic complex IIb reacts instantly with water to give deep violet solutions which slowly decay to yellow solutions. These yellow solutions exhibit strong esr signals typical of Ag(I1) complexes. Analytical data for the new complexes are contained in Table I. Esr spectra were obtained with a Varian E9 X-band spectrometer using quartz tubes for solids and a flat solution cell for aqueous and acetonitrile solutions. Flow experiments were performed by gravity feeding solutions of Ag(II1) complex in acetonitrile and water in acetonitrile into a Y-shaped mixing device 4-5 cm from the cavity connected to a flat solution cell. Infrared spectra were obtained on Nujol mulls using a Perkin-Elmer 457 spectrophotometer. Nmr spectra were obtained on solutions prepared by dissolving Ag(I1) complex in concentrated nitric acid using a Varian AdOA instrument. Evans' meth-

2830 Inorganic Chemistry, Vol. 12, No. 12, 1973

E. Kent Barefield and Michael T. Mocella

Table I. Analytical Data for Silver(I1) and Silver(II1) Complexesa Calcd, % Ia IIa 111

IV Ib IIb

AgC,,H,,N,Cl,O, AgC1,H,,N,Cl,O, AgC,,H,,N,CI,08 AgC,,H,,N,Cl,O, AgC,,H,,N,Cl,O,, AgC,,H,,N,C1,0,,

Found, %

C

H

N

Ag

32.50 23.68 29.85 32.72 27.82 19.80

6.14 4.77 5.73 5.49 5.25 3.99

9.48 11.05 9.95 9.54 8.11 9.24

18.24 21.27 19.15 18.37 15.62 17.78

c1

12.59 15.4

C

H

N

Ag

32.76 24.02 29.67 32.76 28.06 19.25

5.58 4.87 5.87 5.58 5.40 4.08

9.59 11.52 10.35 9.59 8.18 9.11

18.44 21.12 17.76 18.44 14.90 17.10

c1

13.06 14.66

Silver analyses tended to be low even when other elemental values were acceptable. Chlorine was particularly difficult for an analyst to do in the presence of silver so these were not routinely performed. Thanks are due t o MI. J. Nemeth and his colleagues for their assistance in the analytical aspects of this work. Q

Table 11. Spectral, Magnetic, and Electrochemical Data for AdlI) and Ag(II1) Complexes I-IV ~

Oxidation Complex state

haxb

gllc

glc

Anodic wavee

I

t2

2.2

348 (7.7) 280 (3.6)

2.11

2.05gd

0.617 (1)

t3 t2

Diamagnetic

g

I1

1.95

342 (13.3) 275 sh (3)

2.095

2.038

0.71 (1)

t3 +2

Diamagnetic

g

111

1.81

1.997

2.07

0.96 (1)

f

IV

f2

1.96

382 (8.6) 300 (2) 338 (6.2) 300 (6.2)

0.63 (1)

-0.37 (2)

PefP

Cathodic wavee

-0.283 (2) -0.26 (2) 0.68 ( l ) , -0.27 (2)

a Faraday measurements. b M complex, lo-' M (C,H,),NClO, in CH,CN; band position in nanometers, molar extinction coefficient X l O - , in parentheses. C Polycrystalline samples at room temperature unless otherwise noted. d Doped into Ni(I1) complex of corresponding ligand %5% level. e Rotating Pt working electrode, Ag 10.1 M Ag+ in acetonitrile reference electrode, IO-' M complex, lo-' M (C,HS),NC1O, in CH,CN; number of electrons given in parentheses. f Very poorly d e f i e d twoelectron wave. g No low energy d-d transitions are observed.

od5 was used to check for paramagnetic species in these solutions using trimethylamine as a standard. Magnetic susceptibility measurements on solids were done by the Faraday method.

Results and Discussion Reaction of silver(1) with macrocyclic tetraaza ligands is a facile process for forming silver(I1) complexes. Although disproportionation is a common process for Cu(I), these represent the first class of Ag complexes to display this behavior. Metallic silver is a by-product in each of these reactions. Kestner and Allred have isolated a silver(1) complex of ligand Ia in acetonitrile under anhydrous conditions.2 We have also found that white precipitates are formed in purified acetonitrile and that some water is necessary for the disproportionation to occur. All of the silver(I1) complexes are yellow to orange and have infrared spectra similar to their nickel analogs. Magnetic moments are in the range 1.9-2.1 BM expected for monomeric d9 complexes (Table 11). These complexes are exceptionally stable compared to previously reported Ag(I1) complexes. They are stable in most solvents in which they are soluble (e.g., acetonitrile, water, ethanol) for a considerable time although solutions prepared with reducing solvents such as ethanol form silver mirrors after some time. Previously reported Ag(I1) complexes are often quite stable in the solid state. In solution, however, they are powerful oxidants with little stability.6 Epr spectra of the silver(I1) complexes are typical of a d9 axial system. In each case g1 and g are well resolved (Table 11). This is expected for a planar ddl complex.' In the case of 111, g,l